Brake



T. L. FAWlCK Dec. 10, 1935.

BRAKE Filed March 25, 1932 5 Sheets-Sheet l Dec. 10, 1935. I T. L. FAWICK 2,023,674

- BRAKE Filed March 25, 1932 5 Sheets-She s? 4 K97 Ni I T. L. FAWICK Dec. 10, 1935.

BRAKE Filed March 25, 1932 5 Sheets-Sheet 5 ,Patentecl Dec. 10, 1935 UNITED STATES PATENT OFFICE 13 Claims.

The present invention relates generally to braking systems and more particularly to fluid braking systems wherein fluid pressures are employed in providing the necessary brake applying forces.

More specifically, it is the principal purpose of the present invention to provide a suction operated braking system, particularly for automobiles, wherein a source of suction is applied to brak- 10 ing means by optionally operated valve means under the control of the operator. By an arrangement of this sort large and heavy vehicles may be brought to a stop without the expenditure of unnecessary amounts of energy on the 15 part of the operator.

Briefly, the present invention contemplates a new and improved .form of suction operated brakes, preferably one for each wheel of the automobile, all of the brakes being connected by suitable conduit means with a source of suction, such as the intake manifold of the automobile motor, a vacuum chamber or reservoir connected,

with either the intake manifold or with some other source of suction, or a vacuum pump.

Another important object of the present invention is the provision of new and improved valve means controlling the application of suction to t the braking means, which valve means is so constructed and arranged that the force re- 30 quired to operate the valve, although small, is proportional to the force applied to the brakes, whereby the operator controls the braking sys-' tem in a manner which simulates the operation of the regular or standard driver-controlled 35 brakes, thereby giving the, right feel to the braking system .to make it operate like a regular braking system but with greater ease.

Other objects and advantages of the present invention will be apparent to those skilled in 40 the art after a consideration of the following detailed description of the preferred structure,

taken in conjunction with the accompanying drawings, in which:

Figure l is a plan view illustrating the applica- 45 tion of the present invention to an automobile;

Figure 2 is a vertical sectional view taken through the front wheel of the automobile, and c showing in detail the various features of the suction operated brake for that Wheel;

50 Figure 3 is a vertical sectional view taken through one of the rear wheels of the automobile;

Figure 4,is a vertical sectional view illustrating in fragmentary form a modified suction operated brake;

Figures 5 and 6 illustrate forms of valves controlling the application of suction to the braking means and which are so constructed and arranged as to give the proper feel when th suction brakes are actuated; 1

Figure 7 illustrates one form of locking means associated with the brake pedal of an automobile for holding the brake controlled by that pedal in looking position, whereby the brake may be used as a parking or emergency brake;

Figure 8 is a second form of locking means for the brake pedal, this locking means being associated with the control valve for the suction operated means so that the operation of the latter automatically releases the locking means of theparking or emergency brake; and

Figural) illustrates the use of a vacuum storage tank as a source of suction.

Referring now to the drawings, the reference numeral l0 indicates the frame of the automobile, which is equipped with front wheels H and I2 and rear wheels I3 and M. The automobile is also equipped with the usual clutch pedal l6 and a brake pedal l1 arranged, as will be explained later in detail, as an emergency or parking brake, the brake pedal ll controlling the application of a brake l9 cooperating with a brake drum 20 fixedly secured to the propeller shaft 2| of the automobile. Obviously, of course, the brake pedal ll may be arranged to control brakes on the front or rear wheels, or both.

,. Turning now to Figure 2, which is a detail of the suction operated braking'means for the left hand front wheel ll of the automobile, the reference numeral 25 indicates the front axle having a yoke piece 26 on which is mounted the steering knuckle 2'! with its steering spindle 28 on which the wheel H is journaled for rotation; The wheel II, as illustrated, comprises a wheel body 30 equipped with a rim 3| and detachably bolted to a wheel hub 33 which is journaled by suitabl bearings on,the steering knuckle spindle 28. To facilitate mounting the wheel body 30 on the hub 33 the latter is provided with a flange 35 to which i is secured not only the wheel body 30 but a brake drum 35. The brake drum is of the cast metal type and is provided with an interior conically formed braking surface 31. and exterior cooling ribs 38. The brake drum 36 is also provided with a centrally disposed, laterally inwardly directed portion 40. This portion is provided so that the hub 33 and the brake drum 40 may be employed with wire wheels, in which case the portion 40 accommodates the laterally inwardly directed flange of the demountable hub to which the inner ends of the wire spokes are connected.

A stationary disc or plate 45 is fixedly mounted on the steering knuckle 21 and forms, in effect,

a stationary support carried by the axle 25 to 5 which suitable brake shoe means may be connected. In the preferred embodiment the stationary support 45 is bolted orv otherwise secured to the steering spindle 21, there being a plate 46 interposed between the stationary support 45 and the steering spindle 21, with suitable gasket means to provide a firm seat therefor. The plate 46 includes an outer flange portion 49 which is extended in a laterally outer direction so as to substantially embrace the inwardly directed portion 40 of the brake drum, whereby the stationary supporting plate 45 as a whole is disposed in the general plane of the braking surface 31. This is primarily for the purpose of providing a simple and compact braking structure for the automobile wheels.

' The brake shoe means is indicated as a whole by the reference numeral 50. The brake shoe 50 is generally annular in form and is disposed concentric with respect to the axis of rotation of the wheel and of the brake drum 36. The body por-- tionof the brake shoe 50 comprises a radially inwardly directed flange 5| and a radially outwardly directed flange portion 52 with a central depressed portion 53 extending in a laterally outer B0 direction so as to lie closely adjacent to the general plane of the stationary support45. The active or frictional braking surface, like the braking surface 31 on the brake drum 36, is of conical formation and includes a conventionalform of 35 brake lining 56 secured to a conical ring member 51, one edge of which is secured, as at 58, to the radially outer flange 52 while the other edge 60 carries a slotted ring 6i adapted to engage over suitable projections carried by the flange 49 of the stationary plate 45, whereby relative rotation between the stationary support and the brake shoe structure is efiectively prevented-while permitting the necessary axial movement of the brake shoe in applying the brake. The ring memher 51, actually the brake shoe proper, may be formed as a continuous ring, or the same may be formed of a plurality of interconnected sections. For moving the brake shoe structure 56 toward the brake drum 36 to stop or retard the rotation of the wheel II, the present invention contem plates the provision of suction or vacuum means for actuating the brake shoemeans. To provide for this construction an annular flexible wall structure in the nature of a bellows diaphragm 16 60 nected between the radially outer flange 52 of the brake shoe structure and the stationary support 45, also being sealed thereto in any desired manner. For example, the bellows H maybe soldered to the flange 52 on the brake shoe structure, while the stationary support 45 may be provided with a small radially outwardly extending flange 12 to which the adjacent edge of the bellows ll may be connected, either by soldering or by spinning a ring about the flange and the associated edge of the bellows H, or any other equivalent means.

As best shown in Figure 2, the connection 58 between the flange portion 52 and the brake shoe 51' is such that a limited amount of relative movement therebetween is accommodated. This is for the purpose of taking care of any backward or forward motion of the brake shoe relative to its support 45, which may be due to wear between the anchor lugs 49 and the slotted portion 6| of the brake shoe or other causes, and which arises from backward or forward motion of the car with the brake set. If this relative movement,- although slight, were imposed on the flexible diaphragms 19 and H, such rocking action might cause the latter to fail. Since the diaphragms l0 and H are flexible, the brake shoe is supported in its axial movement upon the lugs 49.

Preferably, the radially inner and outer be1- lows I0 and H are of the corrugated metal type so as to provide for the necessary axial movement of the brake shoe 56 while defining or establish- 15 ing in connection therewith and with the stationary support 45 a'vacuum or suction chamber I5 which is hermetically sealed and which, when subjected to suction of suflicient degree, is operable to force the brake shoe 59 into frictional 20 contact with the brake drum 36 to stop the rotation of the wheel II. The required evacuation of the suction chamber 15 may be accomplished bore in the supporting plate 45. A conduit 35 88 is connected with the fitting 84 and leads to a source of suction such as the intake manifold of the automobile motor, a suction chamber, a vacuum pump, or any other equivalent means.

The central depressed portions 53 of the brake 40 shoe structure 50 is provided with sleeves 90 which enclose springs 9| biased between the supporting member 45 and the closed ends 93 of the sleeves to resiliently move the brake shoe away from the brake drum when the suction in the 45 chamber 15 is relieved. The depressed portions 53 serve an important function in diminishing the volumetric capacity of the suction chamber 15 while not' materially restricting the surface, whereby a relatively small degree .of suction will 50 apply suflicient braking force to effectively stop thevehicle. Further, the provision of a compact brake structureis by virtue of this construction more easily accomplished.

In order to protect the brakes, and particularly 55 the flexible wall structures, a disc 95 is secured, as by set screws 96, to the brake drum 36. The dis: 95 extends radially inwardly to a point closely adjacent a centrally disposed cup member 91 secured to the stationary member 45 in any manner so desired. To provide for a leak-tight joint between the disc 95, which rotates with the brake drum 36, and the stationary cup member 91, the disc 95 carries. at its radial inner edge packing means 98 fastened in place by a circular strip 99 65 or by any other equivalent means.

The rear wheel construction illustrated in Fig ure 8 is, as far as the brake details-are concerned, substantially identical 'with that described above, therefore the same reference numerals have been 70 assigned to Figure 3 for all of the parts which are identical. It will be noted, however, that in Figure 3 the rear axle, designated by the reference numeral III], has a flange H.- at its outer end into which the fitting 84 is threaded. there 75 Cal aoaaevs being apertures registering with the fitting 84 and disposed in the plate 48 and the associated gaskets, whereby the fitting 84 in Figure 3 com municates with the bores 85, 8! and 80, respective ly, and suction may be applied to the suction chamber of the braking means for the rear wheels. 1

The illustrated constructions are preferred because practically all of the parts comprising the braking system are identical for the several wheels, whether they be front wheels or rear wheels. Where desirable, of course, the braking means for the rear wheels may be particularly adapted to be associated with the rear axle construction, in-which case there may be slight differences between the braking means for the rear wheels and the braking means for the front wheels.

Figure 4 isa fragmentary view illustrating a slightly different form of braking means in which the outer flexible wall structure or diaphragm is in the form of a bellows having corrugations the same as the bellows structure indicated in Figures 2 and 3 by the reference numeral 1I. However, as regards the radially inner flexible wall structure, the form illustrated in Figme 4 is that ofa flexible strip of material, such as rubber or the like, this strip being indicated in Figure 4 by the reference numeral I20. The brake shoe I2I is practically identical with the brake shoe 50 shown in Figures 2 and 3 with the exception of the radially inner flange I23, which is of somewhat different formation. This flange has a turned edge I over which one edge I25 of the rubber strip is received and secured, as by a clamping member I30. When the latter is in place the edge of the rubber strip I20 is hermetically sealed to the brake shoe .structure I2I.

The opposite edge of the flexible strip I20 is fastened to the stationary member 45 by being received between the cup member 91 and the stationary support when the latter is.bolted to the flange III of the rear axle housing. In this connection it is to be noted that the provision of the plate 46 between the stationary support 45 and the axle, either the front axle or therear axle, serves to hold the cup member 91 in place and this feature is taken advantage of, as described, in effectively sealing the inner edge of the strip I20 to the stationary support 45.

Turning now to Figure 1 it will be observed that the conduit means 88 for the front wheels are connected to a T I and that the conduit means 88 from the rear braking means are connected to a 1' I49. The fittings I40 and Ill are connected, respectively, by conduits I49 and 844 with a valve structure indicated generally in Figure 1 by the reference numeral I85. If desired a shut-01f valve I48 may be inserted in the suction line I43 to prevent operation of the front wheel brakes where only rear brakes are preferred. Associated with the valve I45 is a conduit I 48 which leads from'the valve 5 to the intake manifold I50 of the automobile motor. Instead, however, of leading directly to the intake manifold I50 the conduit I88 may be connected with a vacuum storage tank I55, see-Figure 9, or a vacuum pump which, in turn, is connected with the intake manifold I50 through a pipe I50 and a check valve I51 arranged to permit air to be drawn into the intake manifold but which would prevent the passage of air from the intake manifold into the vacuum chamber I55.

One form of the control valve I45 is-illustrated adapted to be closed by a valve closure I8I in detail in Figure 5. The reference numeral I 10 indicates the floor board of the automobile and "I is a pivoted control member in the form of a foot pedal pivotally mounted on a supporting bracket I12 in any desired manner, as by a bolt 5 I15, to the floor board I10. The valvehousing or valve body is indicated by the reference numeral I11 and encloses a valve chamber I18 divided into two portions by a central wall I19. This wall is apertured to provide a valve pi cilrt 10 e two portions of the valve chamber are indicated by the reference numerals I82 and I83, and the suction line I48 from the intake manifold I50 or from the storage chamber I55 opens into'the l5 suction chamber I82, while the suction lines I43 and I44 to the front and rear braking means communicate with the other portion I82 of the valve chamber I18 through a pipe I85.

One side of the valve chamber I18 is closed by 20 a flexible diaphragm I88 sealed in any manner desired to the valve body I11. This diaphragm is connected with the suction valve closure I8i through a spring I90. One method of sealing the diaphragm I88, which preferably takes the form 25 of a rubber disc or the equivalent, is by means of a plate or cap I9I having an air vent I92 and a. flange-portion I93 provided with suitable apertures through which set screws I95 may be passed and which may be threaded into suitable bosses I91 on the valve body or valve housing I11.

An air vent 200 is formed in the valve housing in communication with the valve chamber I18 so that the braking means can be vented to the atmosphere whenever the brakes are not applied. This air vent 200 is controlled by means of an air valve 20I having a free sliding fit on the upper end of a valve stem 203. This valve stem is slidablymounted in the valve housing I11 and has its upper end projecting through the floor boards 40 I10 of the automobile and in a position to be engaged by the foot pedal I1I.

The upper end of the housing I11 is threaded onto an apertured cap member 2I0 having apertures 2I I and riveted to a second cap member 2 I3 l5 which, in turn, is secured as by riveting or the like to a base plate 2I5, bolted to the under side of the floor boards I10. For this purpose the bolt I15 is utilized and a second bolt 2 IB cooperates therewith to secure the members and the valve hous- 50 ing in place on the under side of the floor boards I10. 1

The valve stem 203 has a bushing 220 or is formed with an integral enlargement to provide oil-soaked hair, felt or the like, acting as a filter or cleaner, is disposed between the sleeve 226 and the apertured cap 2I0. By virtue of this construction air may freely pass into the valve chamher I18 and is cleaned by being drawn through the air fllter.

A spring 230 is disposed between the shoulder 222 and one side of the suction valve I8I. The

latter valve also has a free sliding fit on the lower reduced end 23! of the valve stem 208. It will be noted that the shoulder 223 formed at the lower reduced end of the valve stem does not contact with the valve I M but is spaced therefrom a certain distance.

The operation of the above described valve structure is substantially as follows: When the pedal IN is depressed. by the operator, the valve stem 283 is moved downwardly. This moves the shoulder 22I downwardly, which allows the spring 225 to move the air valve 28I to its seat to close off communication between the atmosphere and the valve chamber through the air vent 288. This downward movement of the valve stem 283 also moves the shoulder 222 downwardly, which compresses the suction valve operating spring 238. The compression of this spring moves the suction valve I8I slightly off its seat, whereupon the suction from the manifold I58 or from the vacuum chamber I55 is communicated through the open port into the valve chamber portion I I83, the connection I85, and the suction lines I43 and I44, whereby the application of the brakes is It will be noted, however, that before the air valve 28I was closed the chamber portion I83 was subjected to atmospheric pressure and that one side of the flexible diaphragm I88 was also subjected to atmospheric pressure,

the other side of the flexible diaphragm beingv also subjected to atmospheric pressure through the air vent. I92. However, as soon as the air valve 28I is closed and the suction valve I8I opened, suction is built up in the chamber I83 and the suction lines in communication therewith, so that now there is a pressure differential existing on opposite sides of the flexible diaphragm I88. This pressure difference causes the diaphragm I88 to compress the spring I98 which is sufficient to bias the valve I8I and cause the same to close against the force of the spring 238. Thus, even though the pedal I1I has been depressed slightly to initially open-the valve I8I to set the brakes, the building up of the suction causes the suction valve I8I to close so that the brakes will not then be set any further. If, however, greater braking efiort is needed the pedal "I is depressed further, putting the spring 238 under greater compression, which then opens the valve I 8|, thus subjecting the chamber I83 and the suction lines to greater suction. If the compression of the spring 238 is not too great the building up of additional suction will again cause the diaphragm I88 to close the suction valve I 8| so that the brakes will again not be set harder than desired, but will be held applied as long as the pedal I1I is held down far enough tokeep the air valve 28I closed. If full braking power is desired, the pedal I1I may be further depressed until the shoulder 223 contacts with the suction valve I8I and positively opens the same and holds the same open. As sbon as need for braking is. no longer present the pedal "I is released, which then moves to its upper position and the shoulder 22 I will lift the air valve 28I off its seat, thus venting the braking system to atmospheric pressure and releasing the brakes as described above.

An important feature to be noted in connection with the above described valve is that the suction valve I8I is of relatively small diameter so that a relatively small pressure is all that is required to open the same. Since under most conditions the spring 238 is compressed at various degrees to give the various degrees of braking effort, the feel of this brake control means is substantially the same as a conventional driveroperated brake, that is, a greater pressure is necessary where greater braking effort is required.

A second form of suction control valve is illustrated in Figure 6. This form of valve is sometion line I48 leading to the intake manifold I58 or a vacuum storage chamber I55, see Figure 9. The valve chamber 24I communicates with the connection I85 and one side of the valve chamber 24I is closed by a flexible diaphragm 245 similar to the diaphragm I88 illustrated in Figure 5. However, where in Figure 5 a separate valve closure I8I was described, in Figure 6.the suction valve closure is supplied by the diaphragm 245 itself seating against the circular suction port 242, as indicated by the reference numeral 246. A closure cap 241 is secured to the valve housing 248 by means of cap screws 249 and a spring 25I is confined between the cap 241 and the diaphragm 245. The cap 241 also includes an air vent 254 whereby one side-of the diaphragm is subjected to atmospheric pressure at all times.

As in the case dfFigure 5, the connection I85 and the lines I43 and I44 leading to the suction operated brakes are subjected to atmospheric pressure whenever the brakes are not applied. For this purpose the valve chamber 24I is provided with an air vent 268 which is adapted to be closed by a valve closure 26I mounted for free sliding movement on a valve stem 263 movably mountedin the valve housing 248. The valve closure 26I is of the disc type and when the stem 263 is depressed not only closes the air vent 268 but also closes off the portion 265 of the valve chamber which is defined partly by a portion of the flexible diaphragm 245.

The air valve 26I is provided with a spring 261 biased between the valve closure 26I and a cup member 218 having apertures 21I through which air may pass.- The upper portion of the valve housing 248 is provided with suitable air intake passages or vents 212, and oil-soaked hair or equivalent means is disposed in this portion of the housing and held in place by the cup member 218 so that all air passing into the valve housing 248 is cleaned.

- The valve stem 263 does not connect directly with the diaphragm 245 which, as indicated above, serves as the suction valve closure. The diaphragm 245 carries acentral stud 215 which has a free slidingflt in an interior bore 216 in the stem. The lower end of the stem clears the diaphragm 245 by a certain distance and a spring 288 is confined between a plate 28I carried by the diaphragm 245 and a shoulder 282 formed on the valve stem itself. This suction valve operating spring 288 serves the same purpose as the valve operating spring .238 described above in connection with the form shown in Figure 5.

The pedal "I in Figure 6 is pivoted. to a collar 285 having a pair of apertured ears 286 to receive one end of the pedal. This collar 285 is threaded onto the upper end of the tubular stem 288 forming a part of a supporting plate 289 to which the upper end of the valve housing 248 is connected, as by cap screws 288.

. The operation of the valve means shown in Figure 6 is substantially identical with the operation of the valve means shown in Figure 5.

When the pedal I1I is depressed the valve stem 263 with its shoulder or flange 282 moves downwardly and causes the spring 261 to first close off the air vent 268 and the portion 265 on one side of the diaphragm. 245 from the atmosphere.

what simpler and more compact than the valve Further movement of the valve stem 263 comaoaaeva presses the,va1ve operating spring 230 an amount suflicient to cause it to move the diaphragm 245 away from the suction port 242, whereby suction is then communicated to the lines leading to the braking means. This puts the chamber 265 under a lowered pressure so that the atmospheric pressure acting on the other side of the diaphragm 245 causes the diaphragm to close 01f the suction port 252 against the force of the spring 280, just as described in the modification shown in Figure 5. Thus, the brakes will not be set harder unless the spring 280 is further compressed to apply greater suction to the braking means. After the spring 280 has been fully compressed the upper end of the stud 215 is contacted by the end of the bore 216 so that further pressure on the pedal lll positively opens and holds open the port 242 whereby full braking effort is obtained. As in the modification shown in Figure 5, the greater the braking effort required, the greater the pressure required to be exerted through the stem 263. Thus the proper feel" is obtained.

Obviously, of course, while I have shown a pivoted brake pedal I'll, if desired the upper end of the stem 263 may be provided or formed with I a suitable head so as to be operated directly. In both of the above described valve means a compact arrangement is provided where the valve means is on one side of the floor boards of the automobile while the brake operating pedal is on the other, there being a single means for mounting both of these parts.

As an important feature of the invention embodied in the above described structure, the usual emergency brake lever may be entirely dispensed with. For example, thepresent invention proposes to utilize a brake pedal substantially identical with the conventional service brake pedal now in wide use in place of the usual hand lever, which generally is in .the way. The use of a pedal in this location for an emergency or parking brake is made possible by the provision of ratchet or equivalent locking means for holding this brake pedal applied.

Referring now'to Figure 7, I have illustrated su h a construction, where the reference numeral 300 indicates a brake pedal of more or less conventional construction pivoted as at 30l to the frame of the vehicle and provided with an aperture 303 to receive a brake rod 304. The dash 305 of the automobile carries a bracket 300 to which is pivoted a hand lever 30! projecting outwardly through the instrument panel 308. An

operating link 3l0 extends downwardly from the hand lever, being pivoted thereto as at 3| I. This operating link all! is connected at its lower end with a slidable pawl? suitably mounted in a sleeve M6 fastened to the dash 305. A springpressed ball 3| 1 is carried by the sleeve M8, the ball being adapted to be received in either of the recesses 3 i 9 formed in the pawl 3H5, whereby the pawl may be yieldingly held in either of two positions. One position is that shown in Figure 8, where the pawl 3 l 5 is disengaged from the shank of the brake pedal 800. When in this position the brake will be released as soon as pressure is removed. therefrom. The other position of the pawl is one where the lower end thereof engages the ratchet teeth 325 formed on or secured to the brake pedal. The pawl 3!! may be brought into engaging position by moving the lever 301 downwardly, whereby the pawl will engage one of the teeth 325 and hold the brake pedal 300 in any position to which it has been depressed. Thus the brake 300 may be used as a parking brake by depressing the same to apply the brake, then moving the lever 30! downwardly to engage the pawl 3 l 5 with the ratchet 325.

Figure 8 illustrates another method of arranging ratchet or other locking means for holding the parking brake pedal depressed. In this case the housing of the suction valve is secured to the frame l0 rather than to the floor boards I10, so as to allow the use of a longer valve stem 298. Also, the pedal l'H has been dispensed with and a simple button 290 secured to the upper end of the stem. The lower portion of the brake pedal 300 is formed as a ratchet 3l0 and suitably and pivotally mounted on the frame is a pawl 3| I having'a spring 3l2 causing the pawl to engage the ratchet 3l0 at all times. The spring 3l2v is socured to the pawl 3| I and-to some stationary part of the automobile, such'as the frame l0 or the like. The upper end of the pawl 3H is bifur cated, as indicated at MS, and the valve stem 298 provided with a collar or pin 3H5 whereby the pawl 3| I may be released by depressing the valve stem. Thus, in this form the locking means for the parking brake may be released by temporarily applying the suction operated service brakes by depressing the valve 298.

In both of the forms of my invention as described above, there is an important feature to which attention should be particularly directed.

Where the vacuum chamber is disposed adjacent the brake drum, every time the brake is applied by exhausting some of the air from the chamber a certain amount of heat units are drawn away from the brake as the air is drawn away by the suction applied. The more the brake is applied the greater the heat, but at the same time the greater is the amount of air withdrawn and therefore the greater the amount of heat removed. When the brakes are released air at atmospheric temperature replaces the air withdrawn from the chamber.

These principles are also applicable to braking systems where fluid or fluids other than air may be utilized, or to closed fluid braking systems where the same fluid is exhausted from and subsequently returned to the braking means.

While I have described above the structure in which the present invention is preferably embodied, it is to be understood that, in fact, widely different means may be employed in the practice of the broader aspects'of my invention. For example, where in Figure 9 I have indicated a vacuum storage tank connected with the intake manifold I50 of the engine it is to be understood that a vacuum pump or the equivalent may be employed if desired.

What I claim, therefore, and desire to secure by Letters Patent is:

1. In a fluid braking system, a rotatable member having a brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe adapted to engage said brake drum to apply braking force thereto and including portions disposed on opposite sides of said stationary support, flexible diaphragm means joining the portion of said movable brake shoe opposite said brake drum with said stationary member to establish therebetween a fluid chamber on the side of said stationary support opposite said brake drum, and

-means disposed radially inwardly of said flexible diaphragm means and providing for the evacuation of fluid from said chamber to move said brake shoe into frictional engagement with said ber having a brake drum, a stationary support concentrically disposed with respect to the axis of rotation of said rotatable member, an axial movable concentric brake shoe adapted to be moved into engagement with said brake drum, flexible wall means joined to said stationary support and to one portion of said concentric brake shoe to define therebetween a fluid chamber, the other portion of said brake shoe being adapted to directly engage said brake drum and to rotate relative to said first portion, means anchoring said other portion of the brake shoe to the radially outer peripheral portions of said stationary support, and means operative through fluid pressure diiferences between the interior and exterior of said fluid chamber for moving said brake shoe against the brake drum.

3. In a fluid braking system, an axle, a wheel rotatably journaled thereon, a brake drum carried by said wheel and having a conical interior braking surface, a stationary plate secured to said axle and disposed adjacent and radially inwardly of the conical braking surface of said brake drum, an axially movable brake shoe having a conical friction surface adapted to be moved to contact with said conical brake drum and substantially embracing the peripheral portions of said stationary plate, said brake shoe being cir- ,cular in formation and having radially inner and outer flanges at one side thereof with a centrally disposed depressed portion therebetween, radially inner and outer flexible wall structures connecting said flanges with said stationary plate to form anannular fluid chamber, said depressed portion of the brake shoe being disposed between said inner and outer flexible wall structures to diminish the volumetric capacity of said chamber, and means for varying the pressure of the fluid within said chamber for applying the brake.

4. In a fluid braking system, an axle, a wheel rotatably journaled thereon, a brake drum secured to said wheel, a circular stationary element connected with said axle and disposed adjacent said brake drum, a circular brake shoe having a friction surface engageable with said brake drum and radially inner and outer flanges with a concentric depressed portion therebetween, resilient wall structures connecting said radially inner and out-- er flanges with said stationary element to define a fluid chamber therebetween, a plurality of sleeves carried by said concentric depressed portion, spring means disposed in said sleeve and abutting against said stationary element to urge the brake shoe away from said brake drum, a source of suction, conduit means connected therewith and carried by said stationary element and communicating with the interior of said chamber to apply suction thereto to engage the brake, and valve means controlling the application of suction to said chamber.

5. In a braking system, a rotatable member having a brake drum, a stationary support, a cupshaped member concentrically disposed with respect to the axis of rotation of said rotatable member and having a cylindrical section and a radially inwardly directed section connected with said stationary support, an enclosing cover secured to said drum and extending radially inwardly therefrom to a point closely adjacent the cylindrical portion of said cup-shaped member, and brake operating means carried by the stationary member radially inwardly of the outer diameter of said cup-shaped member and extending radially outwardly to a point between the stationary member and said brake drum.

6. In a fluid braking system, a rotatable mem-' ber having a brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe adapted to engage said brake drum to apply braking force thereto and including portions surrounding the periphery and disposed on opposite sides of said stationary support, flexible diaphragm means joining the portion of said movable brake shoe opposite said brake drum with said stationary member to establish a fluid chamber on the side of said stationary support opposite said brake drum, means connecting the portion of said brake shoe adjacent the brake drum with the radially outer portions of said stationary support for movement relatively thereto, and meansproviding for the evacuation of fluid from said chamber to move said brake shoe into frictional engagement with said brake drum.

7. In a fluid braking system, a rotatable member having a brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe adapted to engage said brake drum to apply braking force thereto and including portions disposed on opposite sides of said stationary support, flexible diaphragm means joining the portion of said movable brake shoe opposite said brake drum with said stationary member to establish a fluid chamber on the side of said stationary support opposite said brake drum, lugs projecting from the other side of said stationary support adjacent the periphery thereof and opposite said fluid chamber, means anchoring the portion of said movable brake shoe adjacent the brake drum to said lugs, and means disposed radially inwardly of said flexible diaphragm means and providing for the evacuation of fluid from said chamber to move said brake shoe into frictional engagement with said brake drum.,

8. In a fluid braking system, a fixed axle, a wheel rotatably journaled thereon, a brake drum having a radially inwardly disposed section connected to said wheel and a radially outer section having a conical interior braking surface, a stationary support carried by said axle and disposed adjacent the radially inwardly disposed section 4 and having its peripheral portion spaced radially inwardly of the conical braking surface on the brake drum, a circular braking member arranged in embracing relation with respect to the peripheral portion of said stationary support in concentric relation with said brake drum and movable axially into braking engagement with the conical braking surface of said brake drum, said braking member including a radially inwardly directed flange arranged at one side of the stationary support opposite the radially inwardly directed section of said brake drum, flexible wall means connecting said flange with said stationary support to form a fluid chamber, conduit means carried by said, stationary support inwardly of 'rected brake shoe section to establish a fluid chamber, separate means disposed substantially at 7 the periphery of said brake shoe means outside of said fluid chamber and extending between the radially outwardly disposed brake drum engaging section of said brake shoe means and the radially outer portions of said stationary support for anchoring the brake shoe thereto while accommodating relative movement therebetween, and means acting through the fluid pressure in said chamber for causing said brake shoe to move into engagement with said brake drum to apply braking force thereto.

10. In a fluid braking system, a rotatable member having a brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe adapted to engage said brake drum to apply braking force thereto and including por tions disposed on opposite sides of said stationary support, flexible diaphragm means disposed on one side of stationary support and connecting one of said oppositely disposed portions therewith to establish a fluid chamber on said one side of said stationary support, means on the other side of said stationary support adjacent the periphery thereof for anchoring said movable brake shoe to said stationary support, and means acting through the fluid pressure in said chamber to move said brake shoe into frictional engagement with said brake drum. I

11. In a fluid braking system, a rotatable member having a brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe adapted to engage said brake drum to apply braking force thereto and including portions disposed on opposite sidesof said stationary support, flexible diaphragm means joining the portion of said movable brake shoe opposite said brake drum with said stationary member to establish a fluid chamber on the side of said stationary support opposite said brake drum, means on the side of said stationary support adjacent the brake drum for anchoring said movable brake shoe to said stationary support, and means providing for the evacuation of fluid from said chamber to move said brake shoe into frictional engagement with said brake drum.

' said brake drum, means acting against said flange 12. In a braking system, a rotatable member having a conical brake drum, a stationary support disposed adjacent said brake drum, a movable brake shoe having a conical braking surface adapted to engage said brake drum to apply braking force thereto and including radially inwardly directed portions disposed on opposite sides of said stationary support, means disposed on one side of said support and cooperating with one of said radially inwardly directed portions for 10 anchoring said brake drum to said stationary support to transmit braking stresses thereto, and means on the other side of said stationary support and reacting thereagainst to move said brake shoe into frictional engagement with said brake drum.

13. In a braking system, a fixed axle, a wheel rotatably journaled thereon, a brake drum having a radially inwardly disposed section connected to said wheel and a radially outer section having a conical interior braking surface, a stationary support carried by said axle and disposed adjacent the radially inwardly disposed section and having its peripheral portion spaced radially i1.-

wardly of the conical braking surface on the brake 25.

drum, a circular braking member arranged in embracing relation with respect to the peripheral portion of said stationary support in concentric relation with said brake drum and movable axially into braking engagement with the conical braking surface of said brake drum, said braking member including a radially inwardly directed flange ar-' ranged at one side of the stationary support opposite the radially inwardly directed section of and the stationary support at said oneside for \controlling the application of the brake, and

means on the other side of said support and cooperating with the portion of said braking mem- 40 ber opposite flange and generally radially outwardly thereof for anchoring said member to said stationary support.

THOMAS L. FAWICK. 

